Abstract
Confining gauge theories contain glueballs and mesons with arbitrary spin, and these particles become metastable at large $N$. However, metastable higher-spin particles, when coupled to gravity, are in conflict with causality. This tension can be avoided only if the gravitational interaction is accompanied by interactions involving other higher-spin states well below the Planck scale ${M}_{\mathrm{pl}}$. These higher-spin states can come from either the QCD sector or the gravity sector, but both these resolutions have some surprising implications. For example, QCD states can resolve the problem since there is a nontrivial mixing between the QCD sector and the gravity sector, requiring all particles to interact with glueballs at tree-level. If gravity sector states restore causality, any weakly coupled UV completion of the gravity sector must have many stringy features, with an upper bound on the string scale ${M}_{\text{string}}\ensuremath{\lesssim}\sqrt{{M}_{\mathrm{pl}}{\mathrm{\ensuremath{\Lambda}}}_{\mathrm{QCD}}/N}$, where ${\mathrm{\ensuremath{\Lambda}}}_{\mathrm{QCD}}$ is the confinement scale.
Highlights
In the early days of quantum chromodynamics (QCD), ’t Hooft pointed out that there is an unconventional systematic expansion obtained by taking the number of colors N → ∞ and the gauge coupling g → 0 with ’t Hooft coupling λ 1⁄4 g2N 1⁄4 fixed [1,2]
Any such confining gauge theory is characterized by a confinement scale ΛQCD where the ’t Hooft coupling becomes strong
The preceding discussion implies that spectating particles and classical shockwaves are ruled out unless we introduce new states in the gravity sector
Summary
In the early days of quantum chromodynamics (QCD), ’t Hooft pointed out that there is an unconventional systematic expansion obtained by taking the number of colors N → ∞ and the gauge coupling g → 0 with ’t Hooft coupling λ 1⁄4 g2N 1⁄4 fixed [1,2] Any such confining gauge theory is characterized by a confinement scale ΛQCD where the ’t Hooft coupling becomes strong. The scaling relation (1) implies that in the exact N 1⁄4 ∞ limit these higher-spin mesons and glueballs behave as stable particles that are free and noninteracting. For it to work a tower of spin-2 glueballs must remove causality violation due to pure graviton exchange between higher-spin glueballs We believe this possibility merits further investigation, since the second scenario would have profound implications
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